001 Stand Alone Low Voltage - Garney Construction

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Section 2: General Authorized Engineering Information 5 Comments: 2.2 —Electrical Noise Solid-state devices are generally more susceptible to electrical noise interference than their electromechanical counterparts. The reasons are straightforward. The operating mechanism for electromechanical devices requires a deliberate input of electrical energy that can be converted into a sustained mechanical force that is strong enough to close the hard contacts and maintain the closure for the duration on the ON cycle. Most random electrical noise signals lack the energy content to produce that magnitude of mechanical force. The operating mechanism for solid-state devices is totally different. The deliberate electric energy input is used to disturb the placement of the electrically charged particles within the molecular structure. This molecular displacement changes the electrical characteristic from that of an insulator to that of a conductor or vice versa. The required energy level is very low. In addition, a sustained signal is not required for components such as SCRs, triacs, and logic gates because these types are self-latching. Most random electrical noise signals are of the momentary low-energy type. Since it is difficult to separate deliberate signals from random noise, the devices are thereby more susceptible. This is cause for special concern regarding the electrical environment and possible need for noise rejection measures. See sections 3.4, 3.4.1, 3.4.2, and 3.4.3. 2.3 Off-State Current Solid-state controls generally exhibit a small amount of current flow when in the off-state condition. Precautions must be exercised to ensure proper circuit performance and personnel safety. The value of this current is available from the manufacturer. Comments: 2.3— Off-State Current Off-state current is also referred to as leakage current in the literature. A solid-state “contact” is a solid block of material that is switched from ON to OFF by a change internally from a conductor to an insulator. Since a perfect insulator does not exist, there is always some leakage current present as long as voltage is applied to the device. The presence of leakage current indicates that OFF does not mean OPEN. The reader is warned that simply turning a solid-state device OFF does not remove the possibility of a shock hazard. Solid-state and electromechanical devices used as inputs to solid-state controls must be compatible with the solid-state equipment with which they are used. Solid-state devices have inherent off-state current, as explained in the preceding paragraph. Electromechanical devices may also permit a small amount of current to flow when the device is in the “open” position due to poor insulation characteristics, which may be subject to further deterioration with age and use. An example is a switching device that employs a carbon brush in contact with an insulating segment of the switch in the off-state, such that a conductive film may be deposited by the brush on the insulating segment. Any input device that could produce an erroneous signal of sufficient magnitude to cause a malfunction of the solid-state equipment, such as unintended turn ON or inability to turn OFF, should not be used with solid-state controls. See also section 3.5.2. Publication SGI-1.1 - August 2009
6 Section 2: General Authorized Engineering Information 2.4 Polarity Incorrect polarity of applied voltages may damage solid-state controls. The correct polarity of solid-state controls should be observed. Comments: 2.4 —Polarity In some instances incorrect polarity can cause damage to controlled equipment or unintended actuation of outputs. This could result in personal injury due to an unexpected response of the controlled equipment or process. See also section 3.3.2. 2.5 Rate of Rise-Voltage or Current (DV/DT or DI/DT) Solid-state controls can be affected by rapid changes of voltage or current if the rate of rise (DV/DT and/or DI/DT) is greater than the maximum permissible value specified by the manufacturer. Comments: 2.5 —Rate of Rise-Voltage or Current (DV/DT or DI/DT) The DV/DT rating specifies the maximum rate at which voltage may be applied to the power terminals of a solid-state device. Voltage applied at a rate exceeding the DV/DT rating can switch the device ON without an input signal being applied. Electrical noise with high frequency content is one source of rapidly changing voltage. Another common source of high DV/DT is an inductive load that is switched off faster than the stored energy can be dissipated. This fast switching produces “inductive kick voltages” that might exceed the DV/DT limit. The DI/DT rating specifies the maximum rate at which current flow may be increased when switching from OFF to ON. Currents that increase faster than the DI/DT rating cause localized hot spots due to current crowding in a small area until the entire cross section can become conductive. This results in gradual degradation of the device. Subsequent operations generally result in over dissipation and short circuit failures even under normal load conditions. The most common situations for high DI/DT are low load impedance, or capacitance loads. Manufacturers of solid-state equipment usually include internal means to limit the rate of rise of voltage and current. Nonetheless, the user should be aware that additional external means may be necessary to adjust to the specific conditions of some installations. 2.6 Surge Current Current of a value greater than that specified by the manufacturer can affect the solid-state control. Current limiting means may be required. Comments: 2.6 — Surge Current The manufacturer may specify allowable surge current. Common practice is to specify the peak sinusoidal current that can be allowed for one-half cycle at line frequency. The intent behind this practice is to give the user Publication SGI-1.1 - August 2009
Page 1 and 2: Garney Construction 785 E Warren Ga
Page 3 and 4: PROJECT SUBMITTAL Project Owner: Wa
Page 5 and 6: Tab 3. Product References Circuit
Page 7 and 8: Practices that Guard against ESD Th
Page 9 and 10: Handling Sensitive Components Corre
Page 11 and 12: What Causes Electrostatic Damage? E
Page 13: If we pick up the chip, it becomes
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Page 40 and 41: Section 5 : Preventive Maintenance
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Page 45 and 46: Important User Information Solid-st
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Page 51 and 52: P-2 Overview Recommended Cable/Wire
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Page 57 and 58: 1-6 Wire/Cable Types Type 3 Install
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2-6 Power Distribution Transformer
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2-8 Power Distribution Table 2.C AC
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2-10 Power Distribution Drive Catal
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2-12 Power Distribution PowerFlex 7
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2-14 Power Distribution 1336 Family
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2-18 Power Distribution Using Power
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2-20 Power Distribution Braking Cho
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3-2 Grounding Grounding PE or Groun
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3-4 Grounding The grounding scheme
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3-6 Grounding Effective Grounding P
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3-8 Grounding Notes: Publication DR
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4-2 Practices Zinc-plated steel is
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4-4 Practices Figure 4.3 Bolt Mount
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4-6 Practices Figure 4.5 Terminatin
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4-8 Practices Do not lay one ground
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4-10 Practices Spacing Notes: 1. Bo
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4-12 Practices Common Mode Current
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4-14 Practices Cable Trays When lay
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4-16 Practices Figure 4.14 Plain Co
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4-18 Practices Conductor Terminatio
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4-20 Practices Notes: Publication D
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5-2 Reflected Wave (CIV) for the ai
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6-2 Electromagnetic Interference Co
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6-4 Electromagnetic Interference Pu
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6-6 Electromagnetic Interference En
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A-2 Motor Cable Length Restrictions
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A-10 Motor Cable Length Restriction
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Glossary-2 Dry Dry locations per Pe
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Glossary-4 Notes: Publication DRIVE
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Index-2 Ungrounded Secondary, 2-3 D
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Index-4 Surge Protection MOV, 2-17
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Product Details and Certifications
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http://raise.rockwellautomation.com
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Yokogawa Corp. of America - Meter &
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Career │ Site Map │ Contact Us
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AMP-TRAP 2000 ® ATQR TIME DELAY/CL
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AMP-TRAP 2000 ® TIME DELAY/CLASS C
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Bussmann ® LOW-PEAK ® Time-Delay
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Bussmann ® LOW-PEAK ® Time-Delay
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Directory: Tools & Resources|Locati
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Directory: Tools & Resources|Locati
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9 KEY BENEFITS Unique protect
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469 SR Motor Protection System 469
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Product Details Product Details Pro
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POTENTIAL TRANSFORMERS THREE PHASE
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PowerFlex 70/700 Production Test Pr
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PowerFlex 70/700 Production Test Pr
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TEST PROCEDURE Test No: TEST 5015-0
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TEST PROCEDURE Test No: TEST 5015-0
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Customer: The Reynolds Co. End User
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Harmonic Estimator Report - Summary
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Harmonic Estimator Report - Spectru
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SMC-Flex Bulletin 150 SMC-Flex Appl
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Bulletin 150 SMC-Flex Table of Cont
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Bulletin 150 SMC-Flex Solid-State .
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Bulletin 150 SMC-Flex Chapter 2 App
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Bulletin 150 SMC Flex Chapter 1 Int
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Bulletin 150 SMC Flex Standard Soft
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Bulletin 150 SMC Flex Figure 1.4: S
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Bulletin 150 SMC Flex Figure 1.6: C
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Bulletin 150 SMC Flex Dual Ramp Sta
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Bulletin 150 SMC Flex Figure 1.10:
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Bulletin 150 SMC Flex Preset Slow S
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Bulletin 150 SMC Flex Slow Speed wi
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Bulletin 150 SMC Flex Electronic Ov
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Bulletin 150 SMC Flex The SMC-Flex
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Bulletin 150 SMC Flex The SMC-Flex
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Bulletin 150 SMC Flex 2 Overview Ap
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Bulletin 150 SMC Flex Figure 2.3: P
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Bulletin 150 SMC Flex Figure 2.5: R
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Bulletin 150 SMC Flex Figure 2.7: C
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Bulletin 150 SMC Flex Figure 2.9: O
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PROTECTIVE MODULE Bulletin 150 SMC
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Bulletin 150 SMC Flex Built-in Comm
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Bulletin 150 SMC Flex Multi-motor A
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Bulletin 150 SMC Flex Part Winding
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Bulletin 150 SMC Flex SMC-Flex Cont
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Bulletin 150 SMC Flex SMC-Flex Cont
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Bulletin 150 SMC Flex Motor Torque
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Bulletin 150 SMC Flex Chapter 4 Des
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Bulletin 150 SMC Flex Petrochemical
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Bulletin 150 SMC Flex Chapter 5 Phi
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Bulletin 150 SMC Flex Chapter 6 Int
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Bulletin 150 SMC Flex There are two
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Bulletin 150 SMC Flex Figure 6.8: S
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Bulletin 150 SMC Flex Chapter 7 Sol
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Bulletin 150 SMC Flex Chapter 8 Ref
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Bulletin 150 SMC Flex Figure 8.2 il
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Bulletin 150 SMC Flex For single ph
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Bulletin 150 SMC Flex Motor Output
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Bulletin 150 SMC Flex PF W = ------
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Bulletin 150 SMC Flex Notes 8-17
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Publication 150-AT002B-EN-P — Jun
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Drives Support > Drive Maintenance
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Drives Support > Drive Maintenance
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SupportPlus For consultation on hig
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SERVICE & SUPPORT Contract Callout
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Table of Contents 1. Introduction 1
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1.2.1 Feeder Input Data Sheet ALL P
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2.1 Motor Starting Study Discussion
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WPS RVSS Study1 - RVSS - MTRI-WPSSW
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2.2.2 SKM TMS Solid State Voltage R
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2500 1250 100 Percent Voltage Study
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2.3.2 SKM TMS 100% Voltage Start Re
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2.3.2 SKM TMS 100% Voltage Start Re
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2.4 SKM TMS 80% Voltage Start This
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2.4.2 SKM TMS 80% Voltage Start Rep
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4. Information 30
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